Atwood's Machine Lab Purpose:The purpose of this lab is to study the acceleration present in a pulley in respect to the difference in load mass. In doing so, the lab will also study the relationship between the masses on the Atwood machine and the resulting acceleration. Background: In a pulley, the heavier mass will accelerate downward while the lighter one accelerates upward at the same rate. The acceleration depends on the difference in the two masses and the total mass. Hypothesis:According to previous life experiences, as the difference in mass increases, the acceleration of the loads will increase. As for the relationship between acceleration and total mass, it is most likely that the acceleration will decrease as the total mass increases because a larger mass will have more inertia, thus have more opposition to acceleration. Apparatus:
computer (preferably high-end and does not take five hours to load)
Vernier computer interface (1)
Logger Pro (1)
Vernier Photogate with Ultra Pulley (1)
mass sets (2)
string (1)
Procedures:Part 1 -
Set up the Atwood's machine with at least 40cm available for the mass to fall
Connect the Photogate with Super Pulley to DIG/SONIC 1 of the interface
Open the file "10 Atwoods Machine" in the provided Logger Pro program
Put 200g as m2 on one side of the pulley and place 200g as m1 on the other side. Record the data and acceleration.
Move 5g from m2 to m1 and record the data.
Position m1 as high as possible on the pulley and make sure it's steady. Click "Collect" on Logger Pro and let m1 drop.
Click "Examine" in Logger Pro for the region of increasing velocity on the newly generated graph. Then, click "Linear Fit" to find the slope which is also the acceleration. Record the acceleration.
Continue to move 5g increments of mass from m2 to m1 and repeat steps 6-7 for each combination. Do this at least 5 times.
Part 2 -
Do steps 1-3 of Part 1.
Put 120g on m1 and 100g on m2.
Repeat steps 6-7 of Part 1.
Add 20g increments to both sides of the pulley, keeping the difference 20g. Record the masses and repeat steps 6-7 from Part 1. Do this at least 5 times. Data:
Table 1: Part 1 – Total Mass Constant
Trial
m1(g)
m1(g)
Acceleration(m/s2)
Δm(g)
mT(g)
1
202
200
0
2
402
2
207
195
0.1771
12
402
3
212
190
0.3811
22
402
4
217
184
0.6281
32
401
5
222
180
0.8297
42
402
Table 2: Part 2 – The Mass Difference Constant
Trial
m1(g)
m1(g)
Acceleration(m/s2)
Δm(g)
mT(g)
1
120
100
0.6538
20
220
2
140
120
0.5922
20
260
3
160
140
0.4111
20
300
4
180
160
0.3829
20
340
5
200
180
0.3487
20
380
Analysis:
The Acceleration vs. Time Difference graph obviously shows that the relationship is linear. In fact, the LSRL equation is y = 0.021x - 0.061 or as a STATS doctor would say, the value of acceleration = 0.021(mass difference) - 0.061. Hence, the acceleration increases as the mass difference increases.4.)
In the linear regression for this relationship for Acceleration vs. Total Mass, the acceleration decreases the total weight increases with a LRSL equation of y = -0.002x + 1.092 where (y) is acceleration and (x) is total mass.
Nonetheless, in a statistical analysis, the residual plot for the linear regression of the Part 2 graph shows that a linear fit does not best represent the data because results in a parabolic nature. According to the graph, it seems a quartic regression best represents the trend of the relationship between Acceleration and total mass. 5.) If a = 0.021(mass difference) - 0.061 and a = -0.002(total mass) + 1.092, then when combined, 2a = 0.021(mass difference) -0.002(total mass)+ 1.031. When simplified, a = 0.0105(mass difference) -0.001(total mass)+ 0.5155.
If instead, the quartic equation where y = -7E-09x4 + 9E-06x3 - 0.003x2 + 0.759x - 54.27 is used, the combined equations will be 2a =0.021(mass difference)- 7E-09(total mass)4 + 9E-06(total mass)3 - 0.003(total mass)2 + 0.759(total mass) - 54.331. When this is simplified, a = 0.0105(mass difference) -3.5E-09(total mass)4 + 5E-06(total mass)3 - 0.0015(total mass)2 + 0.3795(total mass)- 27.1655.
Conclusion: The hypothesis of this lab is supported by the data collected. As shown by graph 1 of Part 1, the acceleration increases as mass difference increases. Moreover, acceleration decreases as total mass increases. In analysis of graph 1, this result is most likely due to the fact that F = ma, so as mass increases, the net force in one direction increases. In Part 1 of the experiment, m1 gets bigger as m2 gets small in the same increment of grams. The prior results in a greater net force in m1's direction and since F = ma, the net force gradually gets bigger as m1 gets bigger and m2 gets smaller as seen in Table 1. In part two, a linear model did not fit the data very well. This incapability can be seen in a residual plot of the data. Instead, the residual plot suggests a higher powered equation. From examining the general shape of the graph, it seems to be following a quartic pattern. Whether the regression model is linear or quartic, it's evident that, in general, acceleration decreases as total mass increases. The pattern can also be seen in Table 2. And as seen in Table 2, the acceleration decreases at a smaller rate as the total weight increases: in between each interval, the acceleration changes in the respectively 0.0616, 0.1811, 0.0282, then 0.0342 m/s^2. All in all, the data for Part 1 looks fine, but Part 2 could be more accurate. The trend in Part 2 still seems a bit unclear, so more trails will be beneficial to get more points for a better regression line.
Purpose:The purpose of this lab is to study the acceleration present in a pulley in respect to the difference in load mass. In doing so, the lab will also study the relationship between the masses on the Atwood machine and the resulting acceleration.
Background: In a pulley, the heavier mass will accelerate downward while the lighter one accelerates upward at the same rate. The acceleration depends on the difference in the two masses and the total mass.
Hypothesis: According to previous life experiences, as the difference in mass increases, the acceleration of the loads will increase. As for the relationship between acceleration and total mass, it is most likely that the acceleration will decrease as the total mass increases because a larger mass will have more inertia, thus have more opposition to acceleration. Apparatus:
- computer (preferably high-end and does not take five hours to load)
- Vernier computer interface (1)
- Logger Pro (1)
- Vernier Photogate with Ultra Pulley (1)
- mass sets (2)
- string (1)
Procedures:Part 1 -- Set up the Atwood's machine with at least 40cm available for the mass to fall
- Connect the Photogate with Super Pulley to DIG/SONIC 1 of the interface
- Open the file "10 Atwoods Machine" in the provided Logger Pro program
- Put 200g as m2 on one side of the pulley and place 200g as m1 on the other side. Record the data and acceleration.
- Move 5g from m2 to m1 and record the data.
- Position m1 as high as possible on the pulley and make sure it's steady. Click "Collect" on Logger Pro and let m1 drop.
- Click "Examine" in Logger Pro for the region of increasing velocity on the newly generated graph. Then, click "Linear Fit" to find the slope which is also the acceleration. Record the acceleration.
- Continue to move 5g increments of mass from m2 to m1 and repeat steps 6-7 for each combination. Do this at least 5 times.
Part 2 -- Do steps 1-3 of Part 1.
- Put 120g on m1 and 100g on m2.
- Repeat steps 6-7 of Part 1.
Add 20g increments to both sides of the pulley, keeping the difference 20g. Record the masses and repeat steps 6-7 from Part 1. Do this at least 5 times.Data:
Nonetheless, in a statistical analysis, the residual plot for the linear regression of the Part 2 graph shows that a linear fit does not best represent the data because results in a parabolic nature. According to the graph, it seems a quartic regression best represents the trend of the relationship between Acceleration and total mass.
5.)
If a = 0.021(mass difference) - 0.061 and a = -0.002(total mass) + 1.092, then when combined,
2a = 0.021(mass difference) - 0.002(total mass) + 1.031.
When simplified, a = 0.0105(mass difference) - 0.001(total mass) + 0.5155.
If instead, the quartic equation where y = -7E-09x4 + 9E-06x3 - 0.003x2 + 0.759x - 54.27 is used, the combined equations will be
2a =0.021(mass difference)- 7E-09(total mass)4 + 9E-06(total mass)3 - 0.003(total mass)2 + 0.759(total mass) - 54.331.
When this is simplified,
a = 0.0105(mass difference) - 3.5E-09(total mass)4 + 5E-06(total mass)3 - 0.0015(total mass)2 + 0.3795(total mass) - 27.1655.
Conclusion: The hypothesis of this lab is supported by the data collected. As shown by graph 1 of Part 1, the acceleration increases as mass difference increases. Moreover, acceleration decreases as total mass increases.
In analysis of graph 1, this result is most likely due to the fact that F = ma, so as mass increases, the net force in one direction increases. In Part 1 of the experiment, m1 gets bigger as m2 gets small in the same increment of grams. The prior results in a greater net force in m1's direction and since F = ma, the net force gradually gets bigger as m1 gets bigger and m2 gets smaller as seen in Table 1.
In part two, a linear model did not fit the data very well. This incapability can be seen in a residual plot of the data. Instead, the residual plot suggests a higher powered equation. From examining the general shape of the graph, it seems to be following a quartic pattern. Whether the regression model is linear or quartic, it's evident that, in general, acceleration decreases as total mass increases. The pattern can also be seen in Table 2. And as seen in Table 2, the acceleration decreases at a smaller rate as the total weight increases: in between each interval, the acceleration changes in the respectively 0.0616, 0.1811, 0.0282, then 0.0342 m/s^2.
All in all, the data for Part 1 looks fine, but Part 2 could be more accurate. The trend in Part 2 still seems a bit unclear, so more trails will be beneficial to get more points for a better regression line.